PHY 103: Standing Waves and Harmonics. Segev BenZvi Department of Physics and Astronomy University of Rochester
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1 PHY 103: Standing Waves and Harmonics Segev BenZvi Department of Physics and Astronomy University of Rochester
2 Sounds of the Universe NASA/JPL, September
3 Properties of Waves Wavelength: λ, length to repeat peak-peak (trough-trough) Period: τ, time to repeat one cycle of the wave (seconds) Velocity: v = λf, in units of length/time Phase: position within the wave cycle (a.k.a. phase shift or offset) Frequency: f = 1/τ, units of 1/sec (Hertz). Also: ω = 2πf = 2π/τ Wavenumber: k = 2π/λ, in units of 1/meter ( spatial frequency ) Amplitude: A. Energy: E ~ (Amplitude)2 3
4 Behavior of Waves Behavior typical of waves: Reflection: a wave strikes a surface and bounces off Refraction: when a wave changes direction after passing between two media of different densities Diffraction: the bending and spreading of waves around an obstacle, often creating an interference pattern Polarization: the orientation of the oscillation of transverse waves Polarization is not important in acoustics. Why is that? 4
5 Transverse & Longitudinal Waves Sound waves are longitudinal pressure waves; oscillation occurs along the direction of propagation Linear polarization Circular polarization 5
6 Waves on a String Suppose we have a rope of length L, and L is so long that, for now, we don t worry about the ends flopping around We shake and vibrate the rope, sending pulses traveling down its length What are the properties of the wave on this rope? It s speed, its wavelength, etc.? 6
7 Waves on a String Imagine a little piece of the string with length dx. It s under tension, i.e., it feels pulling forces T1 and T2 at each end that try to move the piece up or down F = ma = T T y y 2 y 1y Newton s 2nd Law: force on = T sinθ T sinθ piece of rope with mass m
8 Assumptions Made Angle θ 1 ~ θ2, which means the tension T on each side of the piece is approximately the same The mass of the piece m is really small, so the effect of gravity (F = mg) is negligible compared to T Also note: The total mass of the rope is M and its length is L The mass density of the rope is ρ=m/l, in units of mass per unit length (e.g., g/cm) So the mass of the piece is m = ρ dx 8
9 Waves on a String We also need to sum forces in the x direction: F x = ma x = T 2 x T 1x = T 2 cosθ 1 T 1 cosθ 2 T T Forces along x direction sum to zero; the piece of rope doesn t move side-to-side = 0 9
10 The Wave Equation With a few more substitutions (see overflow slides) Newton s second law reduces to the expression d 2 y dt 2 = T ρ d 2 y dx 2 = v2 d 2 y dt 2, where v = T ρ This is the wave equation that describes the motion of the piece of rope vs. time t and position x. It has two solutions: y(x,t) = Asin(kx ± ωt) = Asin 2π λ (x ± vt), where v = λ f = T ρ Traveling waves, depend on physical properties of the rope 10
11 A Vibrating String In a musical instrument with a vibrating string, the endpoints are fixed so that they don t vibrate Example: a guitar string is fixed at the nut and bridge and will not vibrate at those points What does the wave on the string look like in this case? 11
12 The Plucked String If the string is fixed at both ends, it s going to look something like this when you pluck it: L = λ1/2 L = λ2 L = 3λ3/2 L = 2λ4 12
13 Standing Waves These patterns are called standing waves You can construct a standing wave from a superimposed combination of traveling waves moving in both directions So our earlier conclusions (v = λf = T/ ) are still valid and can be used to describe the fixed string! 13
14 Producing Standing Waves We can create large standing waves in a string by driving it with an oscillating motor (c) UC Davis 14
15 Terminology Nodes: points where the string is fixed (or held) and cannot vibrate Antinodes: points of strongest vibration/oscillation along the length of the string Antinodes Nodes Nodes 15
16 Harmonics/Overtones L = λ/2 f1 = v / λ = v/2l L = λ f2 = v/l = 2f1 L = 3λ/2 f3 = 3v/2L = 3f1 L = 2λ f4 = 2v/L = 4f1 L = 5λ/2 f5 = 5v/2L = 5f1 L = 3λ f6 = 3v/L = 6f1 16
17 Harmonics/Overtones An open string will vibrate in its fundamental mode and overtones at the same time True not just for strings, but all vibrating objects We will demonstrate the presence of overtones by making a spectrogram of a plucked string 17
18 Harmonics/Overtones If a string is touched at its midpoint, it can only vibrate at frequencies with a node at the midpoint The odd-integer harmonics (including the fundamental frequency) are suppressed Question: what will the note sound like? 18
19 Notes and String Length Mathematical relationship between string length and pitch length L/2, frequency 2f length L, frequency f When you halve the string, the pitch goes up by one octave Cutting the string in half means the frequency goes up by 2 One octave = doubling of the frequency of the note Let s try it out with a couple of monochords 19
20 Simple Harp Music Maker lap harp for teaching music to children Very simple layout with 9 identical strings Question: does the string length drop by half as we go up in octaves? Let s measure it Remember: f 1 = v/λ 1 = (T/ )/2L String tension (and density) matter as well as length! 20
21 Piano Strings Instrument makers take advantage of the dependence of f on T and as well as L About 20T of tension (all strings combined) in a grand piano Note: the bass strings are much thicker and denser than the treble strings Otherwise, the frame would need to be 100s of feet long 21
22 Playing the Harp If we pluck G4, what do you expect to observe? In fact, this is the true waveform: 22
23 Spectrogram of the Harp Note the rapid decay of the signal. Why does this happen? frequency overtones fundamental time 23
24 Making Pure Tones If you don t have an open speaker and function generator, you can go here: 24
25 Spectrum of a Pure Tone Pure sine wave looks like a spike at one frequency Noise Noise 25
26 Spectrum of Pure G5 Pure sine wave looks like a spike at one frequency Noise Noise 26
27 Spectrum of Pure G6 Pure sine wave looks like a spike at one frequency Noise Noise 27
28 Pure G4, G5, G6 Note the integer relationship between the pure tones fg4 2fG4 3fG4 4fG4 = 2fG5 28
29 Power Spectrum of G4 29
30 Spectrum of G4 and G5 30
31 Spectrum of G4, G5, & G6 31
32 Harp and Pure Tone: G4 32
33 Harp and Pure Tone: G5 33
34 Harp and Pure Tone: G5 34
35 Cleaning the Spectrogram We can use Audition to remove the overtones from the second pluck in the spectrogram What do you think the second pluck will sound like after cleaning? 35
36 Summary Waves on a string move with velocity v = T/ T is the string tension and is the density Open strings fixed at both ends will exhibit standing waves Increasing number of higher harmonics or overtones Integer multiples of fundamental tone with f 1 = (T/ )/2L Nodes: positions where the string doesn t oscillate Antinodes: positions of maximum oscillation When a string is plucked or driven, all of the overtones can be excited simultaneously. But only some are dominant and determine the timbre 36
37
38 Wave on a Rope: Geometry ma y = T 2,y T 1,y m d 2 y dt 2 = T 2 sinθ 2 T 1 sinθ 1 ρ dx d 2 y dt 2 T sinθ 2 T sinθ 1 T (tanθ 2 tanθ 1 ) forces on rope segment rewrite in terms of angles rewrite m = ρ dx, note that T is the same on both ends if θ small, sine ~ tangent 38
39 The Wave Equation ρ dx d 2 y dt 2 T (tanθ 2 tanθ 1 ) = T dy dy dx dx 2 1 definition of tangent d 2 y dt 2 = T ρ dy dy dx dx 2 1 dx group terms on right side d 2 y dt 2 d 2 y dt 2 = T d 2 y ρ dx 2 = v2 d 2 y dx 2 definition of d 2 y/dx 2 define v 2 = T / ρ 39
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